/*************************************************************************

    sndhrdw\spiders.c

*************************************************************************/
#include "driver.h"
#include "spiders.h"

#define SPIDERS_SOUND_CLK 6000000 /* 6 MHZ*/

/************************************************************************/
/* Spiders Sound System Analog emulation                                */
/* Written by Hans Andersson,  Aug 2005                                 */
/* Schematics by Don Maeby                                              */
/*                                                                      */
/* Todo - Add proper sound mixer                                        */
/************************************************************************/

const struct discrete_dac_r1_ladder spiders_sound_dac =
{
	4,			// size of ladder
	{RES_K(68), RES_K(47), RES_K(33), RES_K(33)}, // R21, R31, R30, R50
	DEFAULT_TTL_V_LOGIC_1,
	0,			// no rBias
	0,			// no rGnd
	0			// no cap
};

/* The noice generator consists of two LS164 plus a LS74, so the lenght is 8+8+1 */
const struct discrete_lfsr_desc spiders_lfsr={
	DISC_CLK_IS_FREQ,
	17,			          /* Bit Length */
	0,			          /* Reset Value */
	4,			          /* Use Bit 4 (QE of first LS164) as F0 input 0 */
	16,			          /* Use Bit 16 (LS74) as F0 input 1 */
	DISC_LFSR_XOR_INV_IN1,/* F0 is XOR with input 1 inverted */
	DISC_LFSR_IN0,		  /* F1 is 1*F0*/
	DISC_LFSR_REPLACE,	  /* F2 replaces the shifted register contents */
	0x000001,		      /* Everything is shifted into the first bit only */
	1,			          /* Output is inverted Q of LS74*/
	16			          /* Output bit */
};


struct discrete_dac_r1_ladder spiders_fire_dac =
{
	1,
	{RES_K(10)},	// R29
	5,				// 555 Vcc
	RES_K(5),		// 555 internal
	RES_K(10),		// 555 internal
	CAP_N(100)		// C100
};

struct discrete_dac_r1_ladder spiders_web_exp_dac =
{
	1,
	{RES_K(10)},	// R44
	5,				// 555 Vcc
	RES_K((5*2.2)/(5+2.2)),		// 555 internal (5k) // R49 (2.2k)
	RES_K(10),		// 555 internal
	CAP_U(0.01)		// C25
};

// IC 10
const struct discrete_555_desc spiders_fire_555a =
{
    DISC_555_OUT_SQW | DISC_555_OUT_DC,
	5,		// B+ voltage of 555
	DEFAULT_555_VALUES
};


const struct discrete_555_desc spiders_super_web_555a =
{
	DISC_555_OUT_DC | DISC_555_OUT_CAP,
	5,		// B+ voltage of 555
	DEFAULT_555_VALUES
};


/* Nodes - Sounds */

#define SPIDERS_WEB_SOUND   NODE_08
#define SPIDERS_NOISE		NODE_09
#define SPIDERS_FIRE		NODE_10
#define SPIDERS_EXPL	    NODE_11
#define SPIDERS_SW_EXPL     NODE_12
#define SPIDERS_SW          NODE_13
#define SPIDERS_X           NODE_14

DISCRETE_SOUND_START(spiders_discrete_interface)

	/************************************************/
	/* Input register mapping for spiders           */
	/************************************************/

	DISCRETE_INPUT_DATA (SPIDERS_WEB_SOUND_DATA)
	DISCRETE_INPUT_DATA (SPIDER_WEB_SOUND_MOD_DATA)
    DISCRETE_INPUT_LOGIC(SPIDERS_FIRE_EN)
	DISCRETE_INPUT_LOGIC(SPIDERS_EXP_EN)
	DISCRETE_INPUT_LOGIC(SPIDERS_SUPER_WEB_EXPL_EN)
	DISCRETE_INPUT_LOGIC(SPIDERS_SUPER_WEB_EN)
    DISCRETE_INPUT_LOGIC(SPIDERS_X_EN)

	/* Web sound */
	DISCRETE_NOTE(NODE_20, 1, SPIDERS_SOUND_CLK/8, SPIDERS_WEB_SOUND_DATA, 255, 15, DISC_CLK_IS_FREQ)
    DISCRETE_TRANSFORM2(NODE_21, 1, NODE_20, SPIDER_WEB_SOUND_MOD_DATA, "01&")
	DISCRETE_DAC_R1(NODE_22, 1, NODE_21, DEFAULT_TTL_V_LOGIC_1, &spiders_sound_dac)

	/* Noise */
	/* LFSR NOISE Should be 3 MHz, but setting it to 6KHz should make no difference (except wasting less CPU cycles) since we sample it
    at 3.75 kHz */
	DISCRETE_LFSR_NOISE(NODE_30, 1, 1, SPIDERS_SOUND_CLK/(1000), 1, 0, 0.5, &spiders_lfsr)
    DISCRETE_SQUAREWFIX(NODE_31, 1, SPIDERS_SOUND_CLK/(10*10*16),1, 50.0, 0.5, 0)	/* 3.75 kHz */
	DISCRETE_SAMPLHOLD(NODE_32,1,NODE_30,NODE_31,DISC_SAMPHOLD_REDGE)

	/* Fire */
	DISCRETE_DAC_R1(NODE_40, 1, NODE_32, DEFAULT_TTL_V_LOGIC_1, &spiders_fire_dac)

	// Fire envelope
	DISCRETE_MULTIPLY(NODE_41, 1, DEFAULT_TTL_V_LOGIC_1, SPIDERS_FIRE_EN)
	DISCRETE_RCFILTER(NODE_42, 1, NODE_41,RES_K(2.2),CAP_U(47)) //R11, C11
	DISCRETE_TRANSFORM4(NODE_43,1, NODE_40, NODE_42, 2.5, 24.5,"012*3/-")

	DISCRETE_555_ASTABLE_CV(NODE_44, 1, RES_K(10), RES_K(22), CAP_N(100), NODE_43, &spiders_fire_555a) //R10, R18, C12
	DISCRETE_MULTIPLY(NODE_45, 1, DEFAULT_TTL_V_LOGIC_1-0.7, SPIDERS_FIRE_EN) // Diode drop D2
	DISCRETE_ASWITCH(NODE_46,1, NODE_44, NODE_45, DISC_CD4066_THRESHOLD)

	/* Explosion */
	DISCRETE_MULTIPLY(NODE_50, 1, DEFAULT_TTL_V_LOGIC_1, SPIDERS_EXP_EN)
    DISCRETE_RCDISC5(NODE_51, 1, NODE_50, RES_M(1),CAP_U(0.47)) //R51, C8
	DISCRETE_MULTIPLY(NODE_52, 1, DEFAULT_TTL_V_LOGIC_1, NODE_32) // Noise 0/1 -> TTL
    DISCRETE_ASWITCH(NODE_53, 1, NODE_52, NODE_51, DISC_CD4066_THRESHOLD)

	/*Super web explosion*/
    DISCRETE_DAC_R1(NODE_60, 1, NODE_32, DEFAULT_TTL_V_LOGIC_1, &spiders_web_exp_dac)
	DISCRETE_555_ASTABLE_CV(NODE_61, 1, RES_K(10), RES_K(22), CAP_N(22), NODE_60, &spiders_fire_555a)  //R48, R47, C24
	DISCRETE_MULTIPLY(NODE_62, 1, DEFAULT_TTL_V_LOGIC_1, SPIDERS_SUPER_WEB_EXPL_EN)
    DISCRETE_RCDISC5(NODE_63, 1, NODE_62, RES_M(1),CAP_U(0.47)) //R9, C9
	DISCRETE_ASWITCH(NODE_64, 1, NODE_61, NODE_63, DISC_CD4066_THRESHOLD)

	/*Super web */
	DISCRETE_555_ASTABLE_CV(NODE_70, 1, RES_K(330), 0, CAP_U(1), -1, &spiders_super_web_555a) //R46, C23
    DISCRETE_MULTIPLY(NODE_71, 1, 57/47, NODE_70) // R27, R28
	DISCRETE_555_ASTABLE_CV(NODE_72, SPIDERS_SUPER_WEB_EN, RES_K(100), RES_K(330), CAP_U(0.01), NODE_71, &spiders_super_web_555a) //R22, R33, C16
    DISCRETE_555_ASTABLE_CV(NODE_73, SPIDERS_X_EN, RES_K(100), RES_K(470), CAP_N(47), NODE_71, &spiders_super_web_555a) // R23, R32, C15

	DISCRETE_ADDER4(NODE_89, 1, NODE_22, NODE_46, NODE_53, NODE_64)
	DISCRETE_ADDER3(NODE_90, 1, NODE_72, NODE_73, NODE_89)

	DISCRETE_OUTPUT(NODE_90, 10000)

DISCRETE_SOUND_END

